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sram_traffic_ws.py
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sram_traffic_ws.py
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import math
from tqdm import tqdm
def sram_traffic(
dimension_rows=4,
dimension_cols=4,
ifmap_h=7, ifmap_w=7,
filt_h=3, filt_w=3,
num_channels=3,
strides=1, num_filt=8,
ofmap_base=2000000, filt_base=1000000, ifmap_base=0,
sram_read_trace_file="sram_read.csv",
sram_write_trace_file="sram_write.csv"
):
# Dimensions of output feature map channel
E_h = math.floor((ifmap_h - filt_h + strides) / strides)
E_w = math.floor((ifmap_w - filt_w + strides) / strides)
# Number of pixels in one convolution window
px_per_conv_window = filt_h * filt_w * num_channels
r2c = px_per_conv_window
# Total number of ofmap px across all channels
num_ofmap_px = E_h * E_w * num_filt
e2 = E_h * E_w
e2m = num_ofmap_px
# Variables to calculate folds in runtime
num_h_fold = 1
num_v_fold = 1
max_parallel_window = 1
# Variables for utilization calculation
util = 0
compute_cycles = 0
if dimension_rows < px_per_conv_window:
num_h_fold = math.ceil(px_per_conv_window/dimension_rows)
else:
max_parallel_window = math.floor(dimension_rows/ px_per_conv_window)
reqd_cols = num_filt # Total number of cols to be mapped
max_cols_per_v_fold = max_parallel_window * dimension_cols
num_v_folds = math.ceil(reqd_cols / max_cols_per_v_fold)
remaining_cols = reqd_cols
cycles = 0
prev_cycl = 0
#print("Vertical folds = " +str(num_v_folds))
# These are the starting addresses of filter weights in the memory
all_col_addr_list = []
for c in range(num_filt):
addr = (c) * r2c + filt_base
all_col_addr_list.append(addr)
# These are the starting addresses of ifmap windows in the memory
hc = ifmap_w * num_channels
all_ifmap_base_addr = []
for px in range(int(e2)): #number of ofmap px in a ofmap channel
addr = (px / E_w) * strides * hc + (px%E_w) * strides
all_ifmap_base_addr.append(addr)
for v in tqdm(range(int(num_v_folds))):
#print("V fold id: " + str(v))
# Take a slice of the starting addresses that are relevant for this v_fold
cols_this_fold = min(remaining_cols, max_parallel_window * dimension_cols)
idx_start = v * dimension_cols
idx_end = idx_start + cols_this_fold
col_addr_list = all_col_addr_list[idx_start:idx_end]
if num_h_fold > 1 :
rem_h = r2c # Tracks the elements processed within a conv filter
next_ifmap_addr = ifmap_base # Starts from the top left corner of the IFMAP matrix
for h in range(num_h_fold):
rows_this_fold = min(rem_h, dimension_rows)
#print("h fold id: " + str(h))
# Values returned
# cycles -> Cycle count for the next operation ie. cycles elapsed + 1
# col_addr_list -> The starting filter address for the next iteration
cycles, col_addr_list = gen_trace_filter_partial(
col_addrs = col_addr_list,
cycle = cycles,
num_rows = dimension_rows,
remaining = rows_this_fold,
sram_read_trace_file = sram_read_trace_file
)
#print("Weights loaded by " + str(cycles) + " cycles")
data_out_cycles = cycles #Store this cycle for parallel readout
cycles_ifmap = gen_trace_ifmap_partial(
cycle = cycles,
num_rows = dimension_rows, num_cols = dimension_cols,
num_filters = num_filt,
remaining = rem_h,
remaining_filters = remaining_cols,
ifmap_h = ifmap_h, ifmap_w = ifmap_w,
filt_h = filt_h, filt_w = filt_w,
num_channels = num_channels,
stride = strides, ifmap_base = ifmap_base,
sram_read_trace_file = sram_read_trace_file
)
cycles_ofmap = gen_trace_ofmap(
cycle = data_out_cycles,
num_rows = dimension_rows,
num_cols = dimension_cols,
ofmap_base = ofmap_base,
window_size= rows_this_fold,
parallel_window =1,
num_ofmap_px = int(e2),
filters_done = (v * dimension_cols),
num_filter = num_filt,
sram_write_trace_file = sram_write_trace_file
)
#print("IFMAPS processed by " + str(cycles) + " cycles")
util_this_fold = (rows_this_fold * cols_this_fold) /(dimension_rows * dimension_cols)
rem_h -= rows_this_fold
cycles = max(cycles_ifmap, cycles_ofmap)
del_cycl = cycles - prev_cycl
util += util_this_fold * del_cycl
compute_cycles += del_cycl
prev_cycl = cycles
else:
#filters_this_fold = min(remaining_cols, max_cols_per_v_fold)
filt_done = v * max_parallel_window * dimension_cols
rem = num_filt - filt_done
parallel_window = math.ceil(rem / dimension_cols)
parallel_window = int(min(max_parallel_window, parallel_window))
cycles_filter = gen_filter_trace(
cycle = cycles,
num_rows = dimension_rows, num_cols = dimension_cols,
filt_h = filt_h, filt_w = filt_w, num_channels = num_channels,
col_addr = col_addr_list,
parallel_window=parallel_window,
filters_this_fold=cols_this_fold,
sram_read_trace_file=sram_read_trace_file
)
cycles_ifmap, rows_this_fold\
= gen_ifmap_trace(
cycle = cycles_filter,
num_rows = dimension_rows, num_cols = dimension_cols,
ifmap_h = ifmap_h, ifmap_w = ifmap_w,
filt_h = filt_h, filt_w = filt_w,
num_channels = num_channels, stride = strides,
parallel_window = parallel_window,
sram_read_trace_file = sram_read_trace_file
)
cycles_ofmap = gen_trace_ofmap(
cycle = cycles_filter,
num_rows = dimension_rows, num_cols = dimension_cols,
ofmap_base = ofmap_base,
parallel_window = parallel_window,
window_size = r2c,
num_ofmap_px = int(e2),
filters_done = int(v * max_parallel_window * dimension_cols),
num_filter = num_filt,
sram_write_trace_file = sram_write_trace_file
)
cycles = max(cycles_ifmap, cycles_ofmap)
del_cycl = cycles - prev_cycl
# Since multiple filters are being mapped on a single col due to large number of rows
# util calculation is a little involved,
# cols_this_fold --> number of filters mapped this fold
rem = cols_this_fold
tmp_util = 0
for _ in range(parallel_window):
col_used = min(rem, dimension_cols)
row_used = r2c # Number of row used will always be in multiple of r2c,
# parallel window calc took care of this
tmp_util += row_used * col_used
rem -= col_used
#util_this_fold = (rows_this_fold * cols_this_fold) /(dimension_rows * dimension_cols)
util_this_fold = tmp_util /(dimension_rows * dimension_cols)
util += util_this_fold * del_cycl
compute_cycles += del_cycl
prev_cycl = cycles
remaining_cols -= cols_this_fold
final = str(cycles)
final_util = (util / compute_cycles) * 100
#print("Compute finished at: " + str(final) + " cycles")
return (final, final_util)
def gen_filter_trace(
cycle = 0,
num_rows = 4, num_cols = 4,
filt_h = 3, filt_w = 3, num_channels = 3,
col_addr = [],
parallel_window = 1,
filters_this_fold = 4,
sram_read_trace_file = "sram_read.csv"
):
outfile = open(sram_read_trace_file,'a')
# There is no data from the left side till the weights are fed in
# This prefix is to mark the blanks
prefix = ""
for r in range(num_rows):
prefix += ", "
# Calculate the convolution window size
r2c = filt_h * filt_w * num_channels
rem = filters_this_fold # Track the number of filters yet to process
#For each wrap around
for w in range(parallel_window):
# Number of active columns in this wrap
cols = min(num_cols, rem)
rem -= cols
# For each row in the window
for r in range(r2c):
entry = str(cycle) + ", " + prefix
cycle += 1
# In each cycle, for each column feed one weight
for c in range(cols):
indx = w * num_cols + c
entry += str(col_addr[indx]) + ", "
col_addr[indx] += 1
if cols < num_cols:
for _ in range(c, num_cols):
entry += ", "
entry += "\n"
outfile.write(entry)
outfile.close()
return cycle
def gen_ifmap_trace(
cycle = 0,
num_rows = 4, num_cols = 4,
ifmap_h = 7, ifmap_w = 7,
filt_h = 3, filt_w = 3,
num_channels = 3, stride = 1,
parallel_window = 1,
sram_read_trace_file = "sram_read.csv"
):
outfile = open(sram_read_trace_file,'a')
postfix = ""
for c in range(num_cols):
postfix += ", "
E_h = math.floor((ifmap_h - filt_h + stride) / stride)
E_w = math.floor((ifmap_w - filt_w + stride) / stride)
e2 = E_h * E_w
r2c = filt_h * filt_w * num_channels
rc = filt_w * num_channels
hc = ifmap_w * num_channels
idle = num_rows - (r2c * parallel_window)
idle = max(idle, 0)
used_rows = num_rows - idle
# Adding entries for columns and empty rows
#print("Idle lanes = " + str(idle))
idle += num_cols
for i in range(idle):
postfix += ", "
postfix += "\n"
base_addr = 0
for e in range(int(e2)):
entry = str(cycle) + ", "
cycle += 1
#print("Cycle= " + str(cycle))
#Inner loop for all the rows in array
num_rows = r2c
row_entry = []
for r in range(num_rows):
row_idx = math.floor(r / rc) # math.floor to get in integral value
col_idx = r % rc
add = base_addr + row_idx * hc + col_idx
#print("Row idx " + str(row_idx) + " col_idx " + str(col_idx) +" add " + str(add))
row_entry.append(add)
# Reverse the printing order
# Reversal is needed because the filter are stored in upside down order in the array
# ie. last row has the first weight element
l = len(row_entry)
#print("Parallel windows = " + str(parallel_window))
for w in range(parallel_window):
#print("Window = " + str(w))
for ridx in range(l):
entry += str(row_entry[l - ridx -1]) + ", "
entry += postfix
outfile.write(entry)
# Calculate the IFMAP addresses for next cycle
px_this_row = (e+1) % E_w
if px_this_row == 0:
#print("New row")
ifmap_row = math.floor(base_addr / hc)
base_addr = (ifmap_row + stride) * hc
else:
base_addr += stride * num_channels
#print("OFAMP px = " + str(e+1) + " base_addr: " + str(base_addr))
outfile.close()
return cycle, used_rows
def gen_trace_filter_partial(
col_addrs=[], #Ensure that this takes care of the v_folding
cycle=0,
num_rows=4,
remaining=4,
sram_read_trace_file="sram_read.csv"
):
outfile = open(sram_read_trace_file, 'a')
num_cols = len(col_addrs)
# output formatting: Add empty commas for row addresses as no element is fed from the left
prefix = ""
for r in range(num_rows):
prefix += ", "
# Entries per cycle
for r in range(remaining): # number of rows this cycle
entry = str(cycle) + ", " + prefix
for c in range(num_cols):
entry += str(col_addrs[c]) + ", "
col_addrs[c] += 1
cycle += 1
entry += "\n"
outfile.write(entry)
outfile.close()
return cycle, col_addrs
def gen_trace_ifmap_partial(
cycle = 0,
num_rows = 4, num_cols = 4,
remaining=4,
num_filters = 8, #
remaining_filters = 0, # These two are used to track the reads of PS
ifmap_h = 4, ifmap_w = 4,
filt_h = 3, filt_w = 3,
num_channels = 3,
stride = 1,
ifmap_base = 0, ofmap_base = 2000000,
sram_read_trace_file = "sram_read.csv"
):
outfile = open(sram_read_trace_file, 'a')
postfix = ""
for c in range(num_cols):
postfix += ", "
postfix += "\n"
r2c = filt_h * filt_w * num_channels
rc = filt_w * num_channels
hc = ifmap_w * num_channels
E_w = (ifmap_w - filt_w + stride) / stride
E_h = (ifmap_h - filt_h + stride) / stride
num_ofmap_px = E_h * E_w
index = r2c - remaining
base_addr = 0
filter_done = num_filters - remaining_filters
#outfile.write(str(filter_done) + ", " + str(num_filters)+", "+str(remaining_filters)+", "+ "\n")
#ofmap_offset = filter_done * num_ofmap_px
ofmap_offset = filter_done
effective_cols = min(remaining_filters, num_cols)
tick = 0 # Proxy for clock to track input skewing
# Outerloop for all ofmap pixels in an ofmap channel
for e in range(int(num_ofmap_px)):
entry = str(cycle) + ", "
cycle += 1
#print("Cycle= " + str(cycle))
#Inner loop for all the rows in array
num_rows = min(num_rows, remaining)
row_entry = []
for r in range(num_rows):
row_idx = math.floor((index+r) / rc) # math.floor to get in integral value
col_idx = (index+r) % rc
add = base_addr + row_idx * hc + col_idx
#print("Row idx " + str(row_idx) + " col_idx " + str(col_idx) +" add " + str(add))
row_entry.append(add)
# Reverse the printing order
# Reversal is needed because the filter are stored in upside down order in the array
# ie. last row has the first weight element
l = len(row_entry)
for ridx in range(l):
entry += str(row_entry[l - ridx -1]) + ", "
# In case of partial mapping
# index > 0 implies that there is a partial sum generated from prev h_fold
# This partial sum is now fed from the top to be summed with the PS generated in this h_fold
# The following part print the read addresses for PS
# Anand : TODO, Implementation choice, do not support right now
'''
if index > 0:
postfix = ""
for c in range(effective_cols):
if (tick - c) > -1: # Track PS reads for skew
a = (e - c) * num_filters + c # e - c: Taking care of skew by c cycles
a = a + ofmap_base + ofmap_offset
postfix += str(a) + ", "
else:
postfix += ", "
tick += 1
#print("Tick =", str(tick) + "Postfix= " + postfix)
postfix += "\n"
'''
entry += postfix
outfile.write(entry)
px_this_row = (e+1) % E_w
if px_this_row == 0:
#print("New row")
ifmap_row = math.floor(base_addr / hc)
base_addr = (ifmap_row + stride) * hc
else:
base_addr += stride * num_channels
#print("OFAMP px = " + str(e+1) + " base_addr: " + str(base_addr))
outfile.close()
return cycle
def gen_trace_ofmap(
cycle = 0,
num_rows = 4, num_cols =4,
ofmap_base = 2000000,
parallel_window = 1,
window_size = 27,
num_ofmap_px = 16, # This is per ofmap channel
filters_done = 0, # To track v fold
num_filter = 8, # To track if all filters have finished
sram_write_trace_file = "sram_write.csv"
):
outfile = open(sram_write_trace_file,'a')
#cycle = num_cols + cycle # Accounts for the time taken to reduce accross all cols
# Corner case when parallel_window = 1, but num_filter < num_cols
if parallel_window > 1:
cycle += num_cols
cycle += window_size # window_size == r2c
else:
rem = (num_filter - filters_done)
cycle += min(rem, num_cols)
cycle += window_size
#ofmap_add_offset = filters_done * num_ofmap_px
ofmap_add_offset = filters_done
remaining_filters = num_filter - filters_done
effective_cols = num_cols * parallel_window
effective_cols = min(effective_cols, remaining_filters)
for e in range(int(num_ofmap_px)):
entry = str(cycle) + ", "
cycle += 1
done = filters_done
for col in range(effective_cols):
if done < num_filter:
a = e * num_filter + col # z first row major
a = a + ofmap_add_offset + ofmap_base
entry += str(a) + ", "
else:
# Code should not enter this part
entry += "!, "
entry += "\n"
outfile.write(entry)
outfile.close()
return cycle
# Trace generation for moving generated ofmap data in cases when only partial window fits
# This implementation prints out the ofmap pixel in the exact cycle it is generated
# Not used in scale sim at the moment.
# SCALE sim waits till all the columns finish generating OFMAP.
def gen_trace_ofmap_partial_imm(
cycle = 0,
num_rows = 4, num_cols =4,
ofmap_base = 2000000,
num_ofmap_px = 16,
num_filter = 8,
filters_done = 0,
sram_write_trace_file = "sram_write.csv"
):
outfile = open(sram_write_trace_file,'a')
start_cycle = num_rows + cycle
col_addr = []
for col in range(int(num_cols)):
a = (filters_done + col)
col_addr.append(a)
for tick in range(int(num_ofmap_px + num_cols)):
cycle = start_cycle + tick
entry = str(cycle) + ", "
for col in range(int(num_cols)):
# Condition to maintain skew
if tick >= col and (tick - col)< num_ofmap_px:
entry += str(col_addr[col]) + ", "
col_addr[col] += num_filter
else:
entry += ", "
entry += "\n"
outfile.write(entry)
outfile.close()
if __name__ == "__main__":
h_h = 5
h_w = 5
r_h = 2
r_w = 2
c = 2
u =1
m = 9
dim_h = 16
dim_v = 5
sram_traffic(
dimension_rows = dim_h,
dimension_cols = dim_v,
ifmap_h = h_h, ifmap_w = h_w,
filt_h = r_h, filt_w = r_w,
num_channels = c,
strides = u,
num_filt = m
)